JP2008153851A - Rfid device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an RFID device for accurately receiving a transmission command from the reader/writer of an affiliated RFID system. <P>SOLUTION: A demodulation circuit 31 of an RFID device is provided with a variable LPF 301 capable of changing a reception band width; a binarization circuit 302 connected to the variable LPF; a transmission speed detection circuit 303 for detecting the transmitting speed of a reception command from the binarization signal; and a control circuit 304 for setting band width corresponding to the maximum transmission speed of a reception command as reception band width in the initial state of the variable LPF, and for changing the reception band width of the variable LPF according to the transmission speed of the reception command. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a high-frequency identifier device called an RFID (Radio Frequency Identification) device. More specifically, when receiving a radio signal transmitted from a reader / writer, the influence of interference with a transmission signal from another RFID system can be reduced. The present invention relates to an RFID device.

  For example, as shown in FIG. 1, the RFID system includes a radio device 10 generally called a reader / writer and a plurality of RFID devices (hereinafter referred to as RFID) 30. The RFID 30 is composed of an IC chip provided with an antenna, and is attached to the article 20 as shown in the figure. The RFID 30 stores identifier information of the article 20.

  Data is written to and read from the RFID 30 in response to transmission of a radio modulated wave indicating the command 40 from the reader / writer 10. Each RFID 30 demodulates the received command 40 and re-emits data (identification information) stored in the memory in response to the command. Hereinafter, transmission data from each RFID 30 is referred to as a response 50.

FIG. 2 shows a format of the command 40 transmitted from the reader / writer 10.
The command 40 includes a preamble (or frame sync) unit 41 and a data unit 42 indicating the command contents. The preamble part 41 is composed of regularly changing “1” and “0” patterns, and each RFID 30 detects the transmission speed of the command during the reception period of the preamble part 41, and the data part at the detected transmission speed. 42 is received.

  Depending on the RFID system, the reader / writer 10 needs to perform wireless communication efficiently with a plurality of RFIDs 30 in a short time. For example, in the protocol of ISO 18000-6C, which is an international standard for UHF band RFID, as shown in FIG. 3, the reader / writer 10 transmits a command A: 40-1 at a predetermined cycle T. Transmission of command B: 40-2, 40-3,... Is repeated at regular time intervals.

  Here, the transmission cycle T of the command A is defined as a “recognition cycle”. Further, the transmission interval of commands (commands A and B) within the recognition period T is defined as “time slot”. That is, the reader / writer 10 according to ISO 18000-6C divides one recognition period T into a plurality of time slots, and transmits a command A or a command B for each time slot.

  The reader / writer 10 instructs each RFID 30 to store the recognition period T and the time slot number N by periodically transmitting a command A indicating the time slot number N. Upon receiving the command A, each RFID 30 randomly selects a time slot to be used in each recognition period T, and transmits a response in response to the received command in this time slot.

  In the example shown in FIG. 3, RFID (# 2) transmits a response 50-1 to command A: 40-1, RFID (# 1), command B: 40 to command B: 40-2. RFID (# 3) transmits the responses 50-2 and 50-3 to -3. Here, for simplicity, each RFID 30 is displayed as transmitting one response 50. Actually, the RFID 30 transmits a pseudo random number called RN16 in response to the command A or the command B, and the reader / writer 10 transmits the received ACK command including the same RN16. Finally, the RFID 30 transmits identifier information called EPC.

  According to this method, the reader / writer 10 can efficiently communicate with a plurality of RFIDs in a short time by setting the recognition period T to an optimum length according to the number of RFIDs 30 to be communicated. become. In addition, the reader / writer 10 designates the identifier (group ID) of the RFID system with each command, so that the response can be returned only to RFIDs belonging to a specific RFID system having the same group ID.

  The frequency band of the carrier wave that can be used in the RFID system is defined by international standards. In the above-mentioned ISO 18000-6C, the carrier frequency band is 860 MHz to 960 MHz, and it is specified that the detailed agreement on the frequency band conforms to the regulations of each country. The carrier frequency band of high-power UHF band RFID in Japan is 952 MHz to 954 MHz, and the bandwidth per channel is 200 kHz.

  For example, when RFID system #A is transmitting a command on a channel having a carrier frequency of 953 MHz, another RFID system #B is transmitting a command using a carrier frequency of 953.2 MHz serving as an adjacent channel. Assume a case. If the command transmission speed in the RFID system #A is 40 kbps, the occupied bandwidth of each command transmitted by amplitude modulation is about 80 kHz.

  When the RFID system #B is operating at a position close to the RFID system #A, the RFID 30 includes a command (amplitude modulation signal) S40 transmitted from the reader / writer of the RFID system #A as shown in FIG. The 200 kHz interference wave S60 due to beat interference arrives. In this case, if the RFID 30 does not have an appropriate reception filter for removing the interference wave S60, the interference wave S60 may cause a bit error in the reception command.

  As a conventional technique for reducing the influence of the interference wave described above, for example, US 2005/0237162 A1 (Patent Document 1) includes one or a plurality of reception filters, and the command is executed with the reception bandwidth set to the minimum. There has been proposed an RFID that detects a transmission rate and readjusts the reception bandwidth to a bandwidth corresponding to the command transmission rate.

  Japanese Patent Laying-Open No. 2003-298664 (Patent Document 2) discloses a multi-rate receiving apparatus having a variable communication bandwidth and transmission speed, and a plurality of low-pass filters having different transmission frequencies and means for detecting transmission speed. (LPF) and an LPF changeover switch, and it has been proposed to select an LPF having optimum characteristics in accordance with the transmission speed of a received signal.

US 2005/0237162 A1 JP 2003-298664 A

  In Patent Document 1, the command transmission rate is detected with the reception bandwidth set to the minimum. Therefore, when the occupied bandwidth of the reception command is wider than the reception bandwidth of the RFID, the high frequency component of the reception signal may be removed, the detection of the transmission speed may fail, and the reception bandwidth of the RFID cannot be adjusted. is there.

  For example, assume that when the reader / writer 10 is transmitting a command on a channel having a carrier frequency of 953 MHz, another RFID system in the vicinity is operating at a carrier frequency of 953.2 MHz serving as an adjacent channel. Here, there are three types of command transmission rates from the reader / writer 10: 40 kbps, 80 kbps, and 160 kbps, and the RFID 30 waits for a command with the minimum reception bandwidth BW30 corresponding to the minimum transmission rate of 40 kbps. To do.

  When the reader / writer 10 transmits the command 40 at the minimum transmission speed of 40 kbps, the occupied bandwidth of the amplitude modulation signal S40 is about 80 kHz. In this case, as shown in FIG. 5A, since the occupied bandwidth of the command is within the reception bandwidth BW30 of the RFID, the RFID 30 eliminates the 200 kHz interference wave S60 generated by beat interference. Thus, the transmission rate can be accurately detected from the preamble portion of the command 40. Therefore, the RFID 30 can readjust the reception bandwidth to an optimum bandwidth according to the transmission speed (in this example, no change is required).

  However, when the reader / writer 10 transmits the command 40 at a transmission rate of 80 kbps, the occupied bandwidth of the amplitude modulation signal S40 is about 160 kHz, and the RFID reception bandwidth BW30 as shown in FIG. Will be exceeded. In this case, since the RFID 30 cannot receive a signal component having a frequency of 80 kHz or more, there is a possibility that the detection of the transmission speed fails and the reception bandwidth cannot be readjusted.

  When the reader / writer 10 transmits the command 40 at a transmission rate of 160 kbps, the occupied bandwidth of the amplitude modulation signal S40 is about 320 kHz, and as shown in FIG. 5C, the RFID reception bandwidth BW30. Is greatly exceeded. In this case as well, there is a possibility that the RFID 30 fails to detect the transmission rate and cannot readjust the reception bandwidth.

  An object of the present invention is to enable each RFID to accurately receive a transmission command from a reader / writer of the RFID system to which the RFID system belongs in an environment where a plurality of RFID systems operate.

In order to achieve the above object, an RFID according to the present invention includes a demodulator that is a part of a receiving circuit, a detector connected to an antenna, a low-pass filter (LPF) unit connected to the detector, A binary circuit connected to the LPF unit,
The LPF unit includes a variable LPF whose reception bandwidth can be changed, and the demodulation circuit detects a transmission rate of a received command from an output signal of the binarization circuit, and the transmission rate detection circuit And a control circuit that controls the reception bandwidth of the variable LPF according to the transmission speed of the reception command detected in
The control circuit sets a bandwidth corresponding to the maximum transmission rate of the reception command as the initial reception bandwidth of the variable LPF, and according to the transmission rate of the reception command detected by the transmission rate detection circuit, The reception bandwidth of the variable LPF is changed.

  In another embodiment of the RFID according to the present invention, the LPF unit is composed of a plurality of LPFs having different reception bandwidths each having a binarization circuit, and the demodulation circuit has a maximum transmission rate of a received command. From the output signal of the binarization circuit connected to the LPF having the corresponding reception bandwidth, the transmission speed detection circuit for detecting the transmission speed of the reception command, and the transmission speed of the reception command detected by the transmission speed detection circuit. And a control circuit that selects one of the plurality of LPFs and uses an output signal of the binarization circuit connected to the LPF as an output signal of the demodulation circuit.

  In still another embodiment of the RFID according to the present invention, the LPF unit includes a plurality of LPFs having different reception bandwidths, each of which includes a binarization circuit, and the demodulation circuit includes the binary signals. A transmission rate detection circuit for detecting the transmission rate of the received command from the output signal of the conversion circuit, and one of the plurality of LPFs is selected according to the transmission rate of the reception command detected by the transmission rate detection circuit. And a control circuit that uses the output signal of the binarization circuit connected to the LPF as the output signal of the demodulation circuit.

  According to the RFID of the present invention, when detecting the transmission speed of a reception command, the reception bandwidth of the LPF can cover the occupied bandwidth of the reception command, so that the transmission speed can be detected correctly. In addition, since the reception bandwidth of the LPF is optimized according to the transmission speed of the reception command, it is possible to receive the command while reducing the influence of the interference wave.

  Embodiments of the present invention will be described below with reference to the drawings.

FIG. 6 is a block diagram showing an embodiment of the RFID 30 according to the present invention.
The RFID 30 includes a demodulation circuit 31, a rectification circuit 32 and a modulation circuit 33 connected to an antenna 38, a decoding circuit 34 connected to the demodulation circuit 31, an encoding circuit 35 connected to the modulation circuit 33, and a decoding The control unit 36 is connected to the encoding circuit 34 and the encoding circuit 35, and the nonvolatile memory 37 is connected to the control unit 36. These elements 31 to 37 are incorporated in the IC chip.

  The rectifier circuit 32 is a source for generating a power supply voltage necessary for the operation of the RFID 30. The memory 37 stores information such as a system identifier and an RFID identifier. As will be described later, the command received by the antenna 38 is converted into a binary signal by the demodulation circuit 31, decoded into digital data (command) by the decoding circuit 34, and input to the control unit 36.

  When the received command is command A, the control unit 36 stores the number of time slots indicated by the command A, randomly selects a target time slot to be responded, and waits for reception of the command in the target time slot. When the control unit 36 receives a command in the target time slot, the control unit 36 transmits a response 50. However, when the target time slot is the time slot of the command A, the control unit immediately transmits the response 50.

  The response 50 (actually, the RN 16 and the EPC) includes the RFID identifier read from the memory 37 and other information. The response is encoded by the encoding circuit 35, amplitude-modulated by the modulation circuit 33, and then wirelessly transmitted from the antenna 38. It is transmitted as a signal.

FIG. 7 shows a first embodiment of the demodulation circuit 31.
The demodulation circuit 31 includes a detector 300 for removing the carrier frequency component from the received signal of the antenna 38, a low-pass filter (LPF) unit 301 for removing the interference wave component from the output signal S300 of the detector 300, and an LPF Including the binarization circuit 302 connected to the unit 301, the output signal of the binarization circuit 302 becomes the output signal S 310 of the demodulation circuit 31.

  In the first embodiment, the LPF unit 301 is composed of a variable LPF whose reception bandwidth can be changed, and the transmission bandwidth detection circuit 303 and the LPF control circuit 304 adapt the reception bandwidth of the variable LPF 301 to the command transmission rate. Yes. The feature of the first embodiment is that the LPF control circuit 304 controls the bandwidth of the variable LPF 301 in a state in which the reception bandwidth of the variable LPF 301 is initially set to the occupied bandwidth when the command transmission speed is maximum when each command is received. The point is to start. The transmission rate detection circuit 303 detects the command transmission rate from the output of the binarization circuit 302 within the reception period of the command A preamble (or frame sync) 41, and outputs the detection result to the LPF control circuit 304. The control circuit 304 controls the bandwidth so that the reception bandwidth of the variable LPF 301 becomes a predetermined occupied bandwidth corresponding to the command transmission rate detected by the transmission rate detection circuit 303.

  In this embodiment, a variable LPF is used in the demodulation circuit for the purpose of removing or reducing the influence of the interference wave. However, in a wireless device, a band pass filter may be used for the same purpose. However, the band-pass filter has a constant reception bandwidth, and the center frequency of the filter is changed according to the frequency band desired to be received. Therefore, for example, if the center frequency of the filter is increased in order to receive a signal in a high frequency band, there is a problem that a signal component in a low frequency band that is out of the reception band cannot be received. This problem is not in LPF.

Next, the operation of the demodulation circuit 31 shown in FIG. 7 will be described with reference to FIGS.
For example, assume that when the reader / writer 10 transmits a command as an amplitude modulation signal on a channel having a carrier frequency of 953 MHz, another RFID system operates at a carrier frequency of 953.2 MHz serving as an adjacent channel. . In the demodulating circuit 31 of the present embodiment, the transmission speed of the received command is detected while the initial reception bandwidth of the variable LPF 301 is initially set to the occupied bandwidth when the command is transmitted at the maximum speed.

  When the reader / writer 10 has a command transmission rate of two steps of 40 kbps or 80 kbps, the reception bandwidth of the variable LPF 301 is initially set to an occupied bandwidth of 160 kHz corresponding to the maximum transmission rate of 80 kbps. When the reader / writer 10 has a command transmission rate of three steps of 40 kbps, 80 kbps, and 160 kbps, the initial reception bandwidth of the variable LPF 301 is set to an occupied bandwidth of 320 kHz corresponding to the maximum rate of 160 kbps. When the transmission speed of the received command is determined, the reception bandwidth of the LPF 301 is switched to an optimum bandwidth that matches the command transmission speed.

  When the actual transmission rate of the command 40 transmitted from the reader / writer is the slowest 40 kbps, the occupied bandwidth of the command is about 80 kHz. If the initial reception bandwidth is 160 kHz, the variable LPF 301 can pass through all frequency components of the reception command and can eliminate the 200 kHz interference wave generated by beat interference, so the transmission speed of the reception command can be detected without any problem. However, when the initial reception bandwidth is 320 kHz, the initial reception bandwidth BW30 of the variable LPF 301 includes not only the occupied bandwidth of the command 40 (amplitude modulation signal S40) but also the beat as shown in FIG. Since a 200 kHz interference wave S60 generated by the interference is also included, there is a possibility that an error may occur in the detection of the command transmission speed depending on the situation of another RFID system in the surroundings.

  When the command transmission rate is correctly detected by the transmission rate detection circuit 303, the reception bandwidth BW30 of the variable LPF 301 is readjusted to a bandwidth suitable for the actual command transmission rate of 80 kHz by the LPF control circuit 304. The readjusted reception bandwidth BW30 covers the occupied bandwidth 80 kHz of the command of 40 kbps and excludes the interference wave S60. Therefore, the command part after the preamble is received without being affected by the interference wave S60. It becomes possible.

FIG. 9 shows the relationship between the signal power-to-interference power ratio (CIR) of the RFID after adjustment of the reception bandwidth and other carrier frequencies that become interference waves (vertical axis: CIR, horizontal axis: carrier frequency). .
When there is no reception filter, the CIR to which the RFID 30 can respond is 29 dB. It can be seen that when the reception bandwidth of the RFID 30 is readjusted to 80 kHz, the CIR is improved by about 11 dB compared to the case without the reception filter, and the influence of the interference wave is reduced.

  When the actual transmission rate of the command 40 is 80 kbps, the occupied bandwidth of the command 40 is about 160 kHz. If the initial reception bandwidth is 160 kHz, the variable LPF 301 can pass through all frequency components of the reception command and exclude the 200 kHz interference wave generated by beat interference, so that the transmission speed of the reception command can be detected without any problem. When the initial reception bandwidth is 320 kHz, as shown in FIG. 8B, the initial reception bandwidth BW30 of the variable LPF 301 is generated by the occupied bandwidth of the 80 kbps command (amplitude modulation signal S40) and beat interference. Since it includes the 200 kHz interference wave S60, an error may occur in the detection of the command transmission rate.

  When the command transmission rate is correctly detected by the transmission rate detection circuit 303, the LPF control circuit 304 readjusts the reception bandwidth BW30 of the variable LPF 301 to a bandwidth adapted to the actual command transmission rate of 160 kHz. The readjusted reception bandwidth BW30 covers the occupied bandwidth 160kHz of the command and excludes the interference wave S60. When the reception bandwidth of the RFID 30 is readjusted to 160 kHz, as shown in FIG. 9, it can be seen that the CIR that can respond to the RFID is improved by about 4 dB compared to the case without the reception filter, and the influence of the interference wave is reduced.

  When the actual transmission speed of the command 40 is 160 kbps, the occupied bandwidth of the command 40 is about 320 kHz. Also in this case, as shown in FIG. 8C, the reception bandwidth BW30 of the variable LPF 301 includes the occupied bandwidth of the command 40 (amplitude modulation signal S40) and the 200 kHz interference wave S60 generated by beat interference. Therefore, an error may occur in the detection of the command transmission rate.

  However, when the command transmission rate is correctly detected by the transmission rate detection circuit 303, the LPF control circuit 304 re-adjusts the reception bandwidth BW30 of the variable LPF 301 to a bandwidth adapted to the actual command transmission rate of 160 kHz. In this case, the readjusted reception bandwidth BW30 includes both the occupied bandwidth 160kHz of the command and the interference wave S60, but as shown in FIG. 9, the CIR that can respond to the RFID 30 is the reception filter. It can be seen that it is improved by about 2 dB from the case of no signal and the influence of the interference wave is reduced.

  According to the first embodiment described above, the command transmission rate is detected while the reception bandwidth of the variable LPF 301 is initially set to the occupied bandwidth when the command is transmitted at the maximum rate. Regardless of the actual transmission rate, the command transmission rate can be detected using all the frequency components of the preamble (or frame sync) portion. In addition, depending on the maximum transmission speed of the command and the state of the interference wave, an error may occur in the transmission speed detection, but if the command transmission speed is detected correctly, the reception bandwidth will be adjusted according to the command transmission speed. It can be seen that the influence of the interference wave can be reduced by optimization.

  The initial setting and optimization of the reception bandwidth of the variable LPF described above can be performed for each command. However, as described later, the initial setting and optimization of the reception bandwidth of the variable LPF described above is executed only when the command A periodically transmitted by the reader / writer 10 every recognition period T is received, and the command B is received. During the period, the reception bandwidth of the variable LPF may be fixed.

FIG. 10 shows a second embodiment of the demodulation circuit according to the present invention applied to RFID.
The demodulation circuit 31 of the second embodiment includes a plurality of LPFs having different reception bandwidths in the output circuit of the detector 300. Here, it is assumed that the reader / writer 10 transmits each command as an amplitude modulation signal at a transmission rate of 40 kbps, 80 kbps, or 160 kbps. In this case, the output signal S300 of the detector 300 is input to the first, second, and third LPFs (311A, 311B, 311C) having reception bandwidths of 80 kHz, 160 kHz, and 320 kHz, respectively, and the output of each LPF unit The signals are converted into binary signals 310A, 310B, and 310C by the binarization circuits 312A, 312B, and 312C.

  In this embodiment, the binary signals 310A, 310B, and 310C are input to the selector 315, and the binary signal 310C connected to the third LPF having the maximum reception bandwidth is input to the transmission rate detection circuit 313. ing. The control circuit 314 controls the selector 315 so that the LPF binary signal suitable for the command transmission rate detected by the transmission rate detection circuit 313 is used as the output S310 of the demodulation circuit.

  Similar to the transmission speed detection circuit 303 of the first embodiment, the transmission speed detection circuit 313 detects the command transmission speed from the binary signal 310C within the reception period of the preamble (or frame sync) portion of the command A, and detects the detection result. Is output to the control circuit 314. The control circuit 314 determines the output of the transmission rate detection circuit 313, selects an LPF unit having a reception bandwidth corresponding to the transmission rate, and sets the selector 315 so that the binary signal becomes the demodulation circuit output S310. I have control.

FIG. 11 shows an example of a specific circuit configuration of the LPF unit 311 indicated by a broken line in FIG.
The LPF unit 311 includes first, second, and third resistance elements R1, R2, and R3 connected in series with each other, and first and second resistance elements connected in parallel between the output terminal of each resistance element and the ground potential. , And third capacitive elements C1, C2, and C3. R1 and C1 form a first LPF: 311A, R1, R2, C1, and C2 form a second LPF: 311B, and R1 to R3 and C1 to C3 form a third LPF: 311B. Output signals from these LPFs are supplied in parallel to the binarization circuits 312A, 312B and 312C.

  When the transmission speed of the command 40 is 40 kbps, the control circuit 314 selects the LFP 311A having the reception bandwidth 30A corresponding to the command transmission speed 40 kbps, and the output of the binarization circuit 312A connected thereto is demodulated. The selector 315 is controlled so that the output signal S310 of the circuit is obtained.

  When the transmission rate of the command 40 is 80 kbps, the control circuit 314 selects the LFP 311B having the reception bandwidth 30B corresponding to the command transmission rate of 80 kbps, and the output of the binarization circuit 312B connected thereto is the demodulation circuit 312B. The selector 315 is controlled so that the output signal S310 is obtained.

  When the reader / writer 10 is transmitting the command 40 at a transmission rate of 160 kbps, if another RFID system is operating on an adjacent channel, an interference wave of 200 kHz is generated due to beat interference. If the influence of the interference wave S60 is small, the transmission rate detection circuit 313 can detect the correct command transmission rate of 160 kbps from the output of the binarization circuit 312C. In this case, the control circuit 314 selects the LFP 311C having the reception bandwidth 30C corresponding to the command transmission rate of 160 kbps so that the output of the binarization circuit 312C connected thereto becomes the output signal S310 of the demodulation circuit. , The selector 315 is controlled.

  According to the present embodiment, after the control unit circuit 314 once selects an LPF (binarization circuit) corresponding to the command transmission speed, there is an improvement effect similar to that of the first embodiment described in FIG. . If the occupied bandwidth of the command transmitted at the maximum transmission rate is lower than the frequency of the interference wave (for example, 160 kHz), the transmission rate detection circuit 313 uses the output of the binarization circuit corresponding to the maximum transmission rate. The correct command transmission rate can be detected.

FIG. 12 shows a third embodiment of the demodulation circuit according to the present invention applied to RFID.
Similar to the second embodiment, the demodulation circuit 31 of the third embodiment includes first, second, and third LPFs (311A, 311B, 311C) having different reception bandwidths, and 2 in the output circuit of the detector 300. There are provided valuation circuits 312A, 312B and 312C. Here, as in the second embodiment, the reader / writer 10 transmits each command as an amplitude modulation signal at a transmission rate of 40 kbps, 80 kbps, or 160 kbps. Accordingly, the reception bandwidths of the first, second, and third LPFs (311A, 311B, 311C) are 80 kHz, 160 kHz, and 320 kHz, respectively.

  In this embodiment, binary signals 310A, 310B, and 310C are input to the transmission rate detection circuit 313. The transmission rate detection circuit 313 detects the command transmission rate from the binary signals 310A, 310B, and 310C within the reception period of the preamble (or frame sync) portion of the command A, and outputs the detection result to the control circuit 314. The control circuit 314 determines the output of the transmission rate detection circuit 313, selects an LPF having a reception bandwidth corresponding to the transmission rate, and controls the selector 315 so that the binary signal becomes the demodulation circuit output S310. To do.

  13A, 13B, and 13C respectively show the reception bands 30A, 30B, and 30C of LPFs: 311A, 311B, and 311C, the interference wave S60, and the occupied band of the reception command (amplitude modulation signal S40). Shows the relationship.

  When the transmission speed of the command 40 is the slowest 40 kbps, the LPFs 311A and 311B pass through the entire band of the received command and block the interference wave S60. LPF: 311C passes through the entire band of the received command and the interference wave S60. Accordingly, the transmission rate detection circuit 313 detects a correct command transmission rate of 40 kbps from at least the outputs of the binarization circuits 312A and 312B, and the control circuit 314 detects an LFP 311A having a reception bandwidth 30A corresponding to the command transmission rate of 40 kbps. Selector 315 can be controlled so that the output of binarization circuit 312A connected to this becomes output signal S310 of the demodulation circuit.

  When the transmission rate of the command 40 is 80 kbps, the LPF: 311A passes the low frequency component of the received command and blocks the high frequency component and the interference wave S60. LPF 311B passes through the entire band of the reception command and blocks interference wave S60, and LPF: 311C passes through the entire band of the reception command and interference wave S60.

  In this case, since the waveform and amplitude of the output signal of LPF: 311A are degraded, it is difficult to detect the correct command transmission rate from the output signal of the binarization circuit 312A, but the output signal of 2 connected to the LPF 311B. A binary pulse signal having a command transmission rate is output from the value conversion circuit 312B. Therefore, the transmission rate detection circuit 313 detects the correct command transmission rate of 80 kbps from at least the output of the binarization circuit 312B, and the control circuit 314 selects the LFP 311B having the reception bandwidth 30B corresponding to the command transmission rate of 80 kbps. Thus, the selector 315 can be controlled so that the output of the binarization circuit 312B connected thereto becomes the output signal S310 of the demodulation circuit.

  When the transmission rate of the command 40 is 160 kbps, the LPFs 311A and 311B pass only the low-frequency component of the received command and prevent the high-frequency component and the interference wave S60 from passing. LPF: 311C passes through the entire band of the received command and interference wave S60. In this case, since the output signals of LPFs 311A and 311B have deteriorated waveforms and amplitudes, it is difficult to detect the correct command transmission rate from the output signals of the binarization circuits 312A and 312B.

  If the influence of the interference wave S60 is small, the transmission rate detection circuit 313 can detect the correct command transmission rate of 160 kbps from the output of the binarization circuit 312C. Therefore, the control circuit 314 selects the LFP 311C having the reception bandwidth 30C corresponding to the command transmission rate of 160 kbps, and the output of the binarization circuit 312C connected thereto becomes the output signal S310 of the demodulation circuit. The selector 315 can be controlled.

  According to the present embodiment, after the control unit circuit 314 once selects an LPF (binarization circuit) corresponding to the command transmission speed, there is an improvement effect similar to that of the first embodiment described in FIG. . In the first and second embodiments, since the command transmission rate is detected by the LPF having the reception bandwidth corresponding to the maximum transmission rate of the command, if the reception bandwidth is 320 kHz, 200 kHz When an interference wave exists, an error may occur in the transmission rate detection result. In contrast, in the third embodiment, the command transmission rate is detected using a plurality of LPFs having different reception bandwidths. Therefore, when the occupied band of the command is lower than the frequency of the interference wave, the interference wave Thus, the command transmission rate can be detected without error.

FIG. 14 shows a time chart when the reception bandwidth is optimized every recognition period T.
The reader / writer 10 first transmits the command A (40-1) in each recognition period T, and thereafter repeats the transmission of the command B (40-2, 40-3,...) At regular time intervals. . Here, a case where the command transmission rate is 40 kbps will be described.

  When the RFID 30 includes the variable LPF 301 as in the first embodiment, the LPF control circuit 304 sets the reception bandwidth of the variable LPF 301 to an initial state (320 kHz in this example) in each recognition period T. Then, the command transmission rate is detected during the reception period (T1) of the preamble (or frame sync) unit 41 of the command A. When the command transmission rate is determined, the LPF control circuit 304 readjusts the reception bandwidth of the variable LPF 301 to the occupied bandwidth of the command, in this example, about 80 kHz, in the middle or at the end of the preamble (or frame sync) unit 41. . During the remaining period of the recognition cycle T (T2), the reception bandwidth of the variable LPF 301 is fixed, and the reception bandwidth of the variable LPF 301 is optimized by repeating the same procedure in the next recognition cycle.

  Even when the RFID 30 includes a plurality of LPFs having different reception bands as in the second and third embodiments, the LPF control circuit 304 is in the reception period of the preamble (or frame sync) unit 41 of the command A ( Based on the command transmission rate detected in T1), an LPF having an optimal reception band is selected, and during the remaining period of the recognition period T (T2), the LFP is fixed and the time chart of FIG. 14 is followed. Optimization of the received bandwidth.

  FIG. 14 shows a time chart when the reader / writer 10 transmits a plurality of commands while repeating the recognition cycle T. However, the reader / writer 10 sends the command A and a predetermined number of commands B at regular time intervals. After the transmission, the wireless communication with the RFID may be temporarily terminated, and the same operation may be resumed at an arbitrary time. In this case, the RFID demodulation circuit 31 executes the operation for one cycle shown in FIG. 14 and waits for reception of a new command A.

1 is a diagram illustrating a general configuration of an RFID system. The figure which shows the frame format of the command which the reader / writer 10 transmits in an RFID system. 4 is a time chart showing a relationship between a command transmitted by the reader / writer 10 and a response returned by the RFID 30 in the RFID system. The figure for demonstrating the relationship between the occupation bandwidth of a command, and an interference wave. The figure for demonstrating the relationship between the receiving bandwidth in the receiving circuit of a prior art, and the occupied bandwidth of a received command. The block block diagram of RFID30 to which this invention is applied. The figure which shows 1st Example of the demodulation circuit 31 with which RFID30 of this invention is provided. The figure for demonstrating the relationship between the receiving bandwidth in the demodulation circuit of 1st Example, and the occupied bandwidth of a received command. The figure which shows the improvement effect of CIR in 1st Example. The figure which shows 2nd Example of the demodulation circuit 31 with which RFID30 of this invention is provided. FIG. 11 is a diagram illustrating an example of a specific circuit configuration of the LPF 311 in FIG. 10. The figure which shows 3rd Example of the demodulation circuit 31 with which RFID30 of this invention is provided. The figure for demonstrating the relationship between the receiving bandwidth in the demodulation circuit of 2nd, 3rd Example, and the occupied bandwidth of a received command. The time chart at the time of optimizing a reception bandwidth for every period T.

Explanation of symbols

10: Reader / Writer, 20: Article, 30: RFID, 31: Demodulation circuit, 32: Rectification circuit, 33: Modulation circuit, 34: Decoding circuit, 35: Encoding circuit, 36: Control unit, 37: Memory, 38 : Antenna, 300: detector, 301: variable LPF, 302: binarization circuit, 303: transmission speed detection circuit, 304: LPF control circuit, 311A-311C: LPF, 312A-312C: binarization circuit, 313: Transmission speed detection circuit, 314: control circuit, 315: selector.

Claims (10)

An RFID device that responds to a command transmitted wirelessly from a reader / writer configuring an RFID (Radio Frequency Identification) system,
A demodulation circuit that is a part of the receiving circuit includes a detector connected to the antenna, a low-pass filter (LPF) unit connected to the detector, and a binarization circuit connected to the LPF unit. Become
The LPF unit is composed of a variable LPF whose reception bandwidth can be changed,
The demodulating circuit detects a transmission speed of the received command from the output signal of the binarization circuit, and the variable LPF of the variable LPF according to the transmission speed of the received command detected by the transmission speed detecting circuit. A control circuit for controlling the reception bandwidth,
The control circuit sets a bandwidth corresponding to the maximum transmission rate of the reception command as the initial reception bandwidth of the variable LPF, and according to the transmission rate of the reception command detected by the transmission rate detection circuit, An RFID device characterized by changing a reception bandwidth of the variable LPF.   2. The RFID according to claim 1, wherein the control circuit executes setting of an initial reception bandwidth and change of the reception bandwidth to the variable LPF for each command received from the reader / writer. device.   When the control circuit receives a specific command periodically transmitted by the reader / writer, the control circuit executes the initial setting of the reception bandwidth and the change of the reception bandwidth to the variable LPF, and the next specific command is received. 2. The RFID device according to claim 1, wherein a command from the reader / writer is received while the reception bandwidth of the LPF is fixed until it is set.   When the control circuit receives a specific command received from the reader / writer, it executes the initial setting of the reception bandwidth to the variable LPF and the change of the reception bandwidth until communication with the reader / writer is completed. The RFID device according to claim 1, wherein a reception bandwidth of the LPF is fixed and a command from the reader / writer is received. An RFID device that responds to a command transmitted wirelessly from a reader / writer configuring an RFID (Radio Frequency Identification) system,
The demodulating circuit that is a part of the receiving circuit includes a detector connected to the antenna, a low-pass filter (LPF) unit connected to the detector, and a binarization circuit connected to the LPF. ,
The LPF unit is composed of a plurality of LPFs having different reception bandwidths each including a binarization circuit,
A transmission rate detection circuit for detecting a transmission rate of a received command from an output signal of a binarization circuit connected to an LPF having a reception bandwidth corresponding to the maximum transmission rate of the received command; One of the plurality of LPFs is selected according to the transmission speed of the received command detected by the detection circuit, and the output signal of the binarization circuit connected to the LPF is used as the output signal of the demodulation circuit. An RFID device comprising a control circuit. An RFID device that responds to a command transmitted wirelessly from a reader / writer configuring an RFID (Radio Frequency Identification) system,
A demodulation circuit that is a part of the receiving circuit includes a detector connected to the antenna, a low-pass filter (LPF) unit connected to the detector, and a binarization circuit connected to the LPF unit. Become
The LPF unit is composed of a plurality of LPFs having different reception bandwidths each including a binarization circuit,
The demodulating circuit detects a transmission speed of a received command from the output signal of each of the binarization circuits, and a plurality of the plurality of signals according to the transmission speed of the received command detected by the transmission speed detecting circuit. An RFID device comprising: a control circuit that selects one of the LPFs and uses an output signal of a binarization circuit connected to the LPF as an output signal of the demodulation circuit.   The control circuit includes a selector connected to an output line of each binarization circuit, and the selector is set so that an output signal of the binarization circuit included in the selected LPF becomes an output signal of the demodulation circuit. The RFID device according to claim 5, wherein the RFID device is controlled.   The control circuit selects one of the plurality of LPFs according to the transmission speed of the received command detected by the transmission speed detection circuit when receiving the specific command periodically transmitted by the reader / writer. 7. The RFID device according to claim 5, wherein a command from the reader / writer is received using the selected LPF until a next specific command is received.   Depending on the transmission speed of the received command detected by the transmission speed detection circuit, one of the plurality of LPFs is selected, and the selected LPF is used until communication with the reader / writer is completed. The RFID device according to claim 5, wherein the RFID device receives a command from the reader / writer.   10. The RFID device according to claim 1, wherein the transmission rate of the reception command is detected within a reception period of a preamble or a frame sync positioned at the head of the reception command.

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